SCHOOL OF CHEMICAL ENGINEERING

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教授

夏淑倩

现任职称/职务:英才教授/副处长,新工科中心执行主任,博士生导师
通讯地址:天津大学化工学院20-228
电子邮箱:shuqianxia@tju.edu.cn
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论著专利:

1. 教材

化工热力学(第三版),国家十一五规划教材,化学工业出版社,2023

化工热力学(通用型),国家十五、十一五规划教材,化学工业出版社,2009

2. 论文

[1] Xu, J.; Xue, S.; Zhang, J.; Han, Y.; Xia, S. Molecular Design of the Amphiphilic Polymer as a Viscosity Reducer for Heavy Crude Oil: From Mesoscopic to Atomic Scale. Energy & Fuels 2020, 35 (2), 1152–1164.

[2] Xu, J.; Wang, N.; Xue, S.; Zhang, H.; Zhang, J.; Xia, S.; Han, Y. Insights into the Mechanism during Viscosity Reduction Process of Heavy Oil through Molecule Simulation. Fuel 2022, 310, 122270.

[3] Ma, H.; Xia, S.; Li, N.; Wang, T.; Zheng, W.; Yu, T.; Shu, Q.; Han, Y. Emulsifying Stability and Viscosity Reduction for Heavy Crude Oil in Surfactant-Polymer Composite System. Journal of Molecular Liquids 2022, 362, 119713.

[4] Wang, T.; Wang, C.; Ma, H.; Yu, F.; Xia, S.; Han, Y. Preparation of Temperature-Sensitive SiO2–PSBMA for Reducing the Viscosity of Heavy Oil. Energy & Fuels 2023.

[5] Wang, C.; Gao, L.; Liu, M.; Xia, S.; Han, Y. Viscosity Reduction Mechanism of Functionalized Silica Nanoparticles in Heavy Oil-Water System. Fuel Processing Technology 2022, 237, 107454.

[56] Ma, H.; Xia, S.; Sun, C.; Yu, F.; Cameron, A.; Zheng, W.; Shu, Q.; Pei, H.; Han, Y. Novel Strategy of Polymers in Combination with Silica Particles for Reversible Control of Oil–Water Interface. ACS Applied Materials & Interfaces 2022. 15, 1, 2216–2227.

[7] Wang, C.; Gao, L.; Liu, M.; Xia, S.; Han, Y. Self-Crystallization Behavior of Paraffin and the Mechanism Study of SiO2 Nanoparticles Affecting Paraffin Crystallization. Chemical Engineering Journal 2023, 452, 139287.

[8] Li, N.; Ma, H.; Wang, T.; Sun, C.; Xia, S. Effect of Molecular Weight on the Properties of Water-Soluble Terpolymers for Heavy Oil Viscosity Reduction. Journal of the Taiwan Institute of Chemical Engineers 2023, 144, 104738.

[9] Li, N.; Ke, H.; Wang, T.; Xia, S. Recyclable Surface-Functionalized Fe3O4 Particles for Heavy Oil Viscosity Reduction. Journal of Petroleum Science and Engineering 2022, 211, 110112.

[10] Ren, Y.; Xia, S. Synthesis and Mechanism Analysis of a New Oil Soluble Viscosity Reducer for Flow Improvement of Chenping Heavy Oil. Chinese Journal of Chemical Engineering 2022, 45, 58–67.

[11] Chen, X.; Wang, N.; Xia, S. Research Progress and Development Trend of Heavy Oil Emulsifying Viscosity Reducer: A Review. Petroleum Science and Technology 2021, 39 (15–16), 550–563.

[12] Ke, H.; Yuan, M.; Xia, S. A Review of Nanomaterials as Viscosity Reducer for Heavy Oil. Journal of Dispersion Science and Technology 2020, 43 (9), 1271–1282. https://doi.org/10.1080/01932691.2020.1851246.

[13] Sun C, Ma H, Yu F, et al. Preparation and evaluation of hydroxyethyl cellulose–based functional polymer for highly efficient utilization of heavy oil under the harsh reservoir environments[J]. International Journal of Biological Macromolecules, 2024, 259: 128972.